The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak
load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the
highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total
pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water is disposed of through the local wastewater system.

]]>http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak
load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the
highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total
pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water is disposed of through the local wastewater system.]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-21.84350300,64.52124700AlbinoFlea (VirtualGlobetrotting)
By: AlbinoFlea. Read more...
From http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water isdisposed of through the local wastewater system.

]]>http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water isdisposed of through the local wastewater system.]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-21.81713100,64.52799300AlbinoFlea (VirtualGlobetrotting)
By: AlbinoFlea. Read more...
From http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water

is disposed of through the local wastewater system.

]]>http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water isdisposed of through the local wastewater system.

]]>http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak

load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the

highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total

pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water isdisposed of through the local wastewater system.]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-21.86021800,64.37596400KRL (VirtualGlobetrotting)
By: KRL. Read more...
Navy 1; Coso Hot Springs, China Lake. Surface pipelines from wells visible. Two other operational plants and one under construction to the south. Link to more info.

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak
load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the
highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total
pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water is disposed of through the local wastewater system.

]]>http://www.geothermie.de/egec-geothernet/ghc/19-4art3.pdf:

The springs at Deildartunga supply 180 L/s of water at
96oC and the wells at Baer can produce about 20 L/s in artesian
flow. Thus, the combined supply capacity is 200 L/s.
Currently, however, the system is using only 170 L/s at peak
load, which are taken from the Deildartunga hot springs. The
wells at Baer are only used if the supply from Deildartunga is
interrupted for some reason and flows cannot be maintained
by the storage tanks.
The collection system at the springs is very simple. An
arrangement of low walls guides the boiling water into the
collection pipes. These conduct the fluid to a nearby pumping
station that pumps the water up to a storage tank at the
highest point in the pipeline at Kroppsmuli a few km away.
The system also includes two storage tanks to maintain supplies
to Akranes and Borgarnes if breaks in the transmission
pipeline occur. The tank at Borgarnes has a capacity of 2,500
m3 and that at Akranes 2,000 m3. These give the
nmaanicnete c-rews several hours in which to repair breaks. Pumping
stations are at six different places in the system.
The distribution system is a single pipeline system, made
of buried steel pipes, pre-insulated by polyurethane. The total
pipe length of the distribution system is 107 km; thereof,
57 km in Akranes, 23 km in Borgarnes and 27 km in the rural
areas. The water supplied is used directly by the users in their
is disposed of through the local wastewater system.
radiator systems and as domestic hot water. The return water is disposed of through the local wastewater system.]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-22.03540900,64.33251500kaiken (VirtualGlobetrotting)
By: kaiken. Read more...

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-89.41850800,13.72432000adrbr (VirtualGlobetrotting)
By: adrbr. Read more...
The Tiwi Geothermal Power Plant complex is located in Tiwi, Albay province. It consists of three generating units, namely, Plant A with two 60-MW units, Plant B with two 55-MW units, and Plant C with two 57-MW units. Plant B's Unit 4 was retired or decommissioned in 2003. The complex was first commissioned in 1979. The Power Sector Assets & Liabilities Management Corporation will auction off the complex in June 4, 2008

]]>]]>1root://styleMaps#default+nicon=0x304+hicon=0x314123.64844100,13.46542300kjfitz (VirtualGlobetrotting)
By: kjfitz. Read more...
The Cerro Prieto Geothermal Power Station is the largest geothermal power station in the world, with an installed capacity of 720 MW, with plans for expansion up to 820 MW by 2012.

]]>]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-115.23883000,32.39873300kkeps (VirtualGlobetrotting)
By: kkeps. Read more...
Malitbog Geothermal Power Station is a 232.5 MW geothermal power plant and is the world's largest geothermal power plant under one roof located in Malitbog, Kanangan, Leyte, Philippines.

]]>]]>1root://styleMaps#default+nicon=0x304+hicon=0x314124.64989200,11.15273000kjfitz (VirtualGlobetrotting)
By: kjfitz. Read more...
Several geothermal facilities generate electricity from hot brine that bubbles up from the ground in the Imperial Valley, at the southern end of the Salton Sea. The two plants at Heber generate around 50 megawatts and are operated by the Covanta Energy Company.

]]>]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-115.53613200,32.71437500kjfitz (VirtualGlobetrotting)
By: kjfitz. Read more...
The Wayang Windu Geothermal Power Station is the largest geothermal power station in Indonesia. The facility utilizes two units, one with 110 MW and the other with 117 MW, totalling the installed capacity to 227 MW. The power station is located in Pangalengan, West Java, in Indonesia. An estimated cost of US$200 million was incurred in constructions and development.

]]>]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-154.88873000,19.47768900kjfitz (VirtualGlobetrotting)
By: kjfitz. Read more...
The Reykjanes Power Station is a geothermal power station located in Reykjanes at the southwestern tip of Iceland. As of 2009, the plant produces 100MW of electricity, with an expansion plan to increase by 50MW in 2010.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314176.19333400,-38.61210000kjfitz (VirtualGlobetrotting)
By: kjfitz. Read more...
The Hellisheiði Power Station is the second largest geothermal power station in the world, and the largest in Iceland. The facility is located in Hengill, southwest Iceland, 11 km (7 mi) from the Nesjavellir Geothermal Power Station. As of February 2009, the plant produces 213 MW of electricity, with a target capacity of 300 MW of electricity and 400 MW of thermal energy. Once this capacity is reached, it would rank as the largest geothermal power station in the world, in terms of installed capacity.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x31410.88450678,43.22727295adrbr (VirtualGlobetrotting)
By: adrbr. Read more...
The Wairakei Power Station is a geothermal power station near the Wairakei Geothermal Field in New Zealand. Wairakei lies in the Taupo Volcanic Zone.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314176.04179000,-38.63050800kkeps (VirtualGlobetrotting)
By: kkeps. Read more...
The Krafla Power Station is a geothermal power station located near the Krafla Volcano in Iceland. Since 1999, it produces 60 MW of energy.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314176.29291900,-38.52849900Tyco (VirtualGlobetrotting)
By: Tyco. Read more...
SB Geo Inc. operates four generating plants as a combined facility located near the junction of U.S. Highway 395 and State Route 431. The SB Geo wells produce from fractured material along a north-northeast-striking fault zone. Submersible pump technology application studies at the plant are ongoing, and a high-efficiency turbine retrofit was completed in 2001. The U.S. Department of Energy provided initial funds ($200,000) to Steamboat Envirosystems LLC to evaluate enhanced geothermal systems technology at Steamboat, and $270,000 for geothermal resource exploration and definition through the GeoPowering the West program. In 2001, SB Geo drilled a 610-m temperature slim hole on its Meyberg Property, 1.5 km south of the SB Geo plants. A maximum temperature of 162C between 335 and 427 m was measured; temperatures decrease below this interval.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x31411.03923200,43.17013900jbottero (VirtualGlobetrotting)
By: jbottero. Read more...
Kamojang, popularly known as Kawah Kamojang or (the Kamojang crater), is a geothermal field and tourist spot in West Java, Indonesia. The crater is located in sub-district (kecamatan) Ibun in the Bandung Regency, approximately 45 km to the southeast of Bandung through the towns of Majalaya and Ibun. The crater can also be reached from the opposite direction through the town of Garut, in Garut Regency (the distance by road from Garut to the northwest through the township of Samarang is around 25 km).

The volcano that the crater is located on is Mount Guntur but the crater itself is listed as an active volcano of Indonesia because of its geothermal activities.

]]>
The volcano that the crater is located on is Mount Guntur but the crater itself is listed as an active volcano of Indonesia because of its geothermal activities.]]>1root://styleMaps#default+nicon=0x304+hicon=0x314107.78461800,-7.13853200jbottero (VirtualGlobetrotting)
By: jbottero. Read more...
The Te Huka Geothermal Power Station, also known as Tauhara One, is a 23 MW binary cycle geothermal power station situated near Taupo, New Zealand. The power station is operated by Contact Energy.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-86.54038000,12.39364800jbottero (VirtualGlobetrotting)
By: jbottero. Read more...
This cluster of seven geothermal plants is the largest of three major geothermal energy production sites in the Imperial Valley. A network of deep wells drilled in the geothermal field allow water, heated by the earth's mantle, to come to the surface and to power electrical generators. Owned by the CalEnergy Company, the electricity is sold to the local power utility and put on the grid. The seven plants in this field produce enough electricity to power over 100,000 homes.

]]>1root://styleMaps#default+nicon=0x304+hicon=0x314-36.82030300,-5.38142200jbottero (VirtualGlobetrotting)
By: jbottero. Read more...
The Nesjavellir Geothermal Power Station is the second largest geothermal power station in Iceland. The facility is located 177 m (581 ft) above sea level in the southwestern part of the country, near Thingvellir and the Hengill Volcano.